lldb/source/Core/ValueObjectVariable.cpp - rust-lang/llvm-project - Git at Google

 //===-- ValueObjectVariable.cpp ---------------------------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #include "lldb/Core/ValueObjectVariable.h"

 #include "lldb/Core/Address.h"
 #include "lldb/Core/AddressRange.h"
 #include "lldb/Core/Module.h"
 #include "lldb/Core/Value.h"
 #include "lldb/Expression/DWARFExpression.h"
 #include "lldb/Symbol/Declaration.h"
 #include "lldb/Symbol/Function.h"
 #include "lldb/Symbol/ObjectFile.h"
 #include "lldb/Symbol/SymbolContext.h"
 #include "lldb/Symbol/SymbolContextScope.h"
 #include "lldb/Symbol/Type.h"
 #include "lldb/Symbol/Variable.h"
 #include "lldb/Target/ExecutionContext.h"
 #include "lldb/Target/Process.h"
 #include "lldb/Target/RegisterContext.h"
 #include "lldb/Target/Target.h"
 #include "lldb/Utility/DataExtractor.h"
 #include "lldb/Utility/RegisterValue.h"
 #include "lldb/Utility/Scalar.h"
 #include "lldb/Utility/Status.h"
 #include "lldb/lldb-private-enumerations.h"
 #include "lldb/lldb-types.h"

 #include "llvm/ADT/StringRef.h"

 #include <assert.h>
 #include <memory>

 namespace lldb_private {
 class ExecutionContextScope;
 }
 namespace lldb_private {
 class StackFrame;
 }
 namespace lldb_private {
 struct RegisterInfo;
 }
 using namespace lldb_private;

 lldb::ValueObjectSP
 ValueObjectVariable::Create(ExecutionContextScope *exe_scope,
                             const lldb::VariableSP &var_sp) {
   return (new ValueObjectVariable(exe_scope, var_sp))->GetSP();
 }

 ValueObjectVariable::ValueObjectVariable(ExecutionContextScope *exe_scope,
                                          const lldb::VariableSP &var_sp)
     : ValueObject(exe_scope), m_variable_sp(var_sp) {
   // Do not attempt to construct one of these objects with no variable!
   assert(m_variable_sp.get() != NULL);
   m_name = var_sp->GetName();
 }

 ValueObjectVariable::~ValueObjectVariable() {}

 CompilerType ValueObjectVariable::GetCompilerTypeImpl() {
   Type *var_type = m_variable_sp->GetType();
   if (var_type)
     return var_type->GetForwardCompilerType();
   return CompilerType();
 }

 ConstString ValueObjectVariable::GetTypeName() {
   Type *var_type = m_variable_sp->GetType();
   if (var_type)
     return var_type->GetName();
   return ConstString();
 }

 ConstString ValueObjectVariable::GetDisplayTypeName() {
   Type *var_type = m_variable_sp->GetType();
   if (var_type)
     return var_type->GetForwardCompilerType().GetDisplayTypeName();
   return ConstString();
 }

 ConstString ValueObjectVariable::GetQualifiedTypeName() {
   Type *var_type = m_variable_sp->GetType();
   if (var_type)
     return var_type->GetQualifiedName();
   return ConstString();
 }

 size_t ValueObjectVariable::CalculateNumChildren(uint32_t max) {
   CompilerType type(GetCompilerType());

   if (!type.IsValid())
     return 0;

   ExecutionContext exe_ctx(GetExecutionContextRef());
   const bool omit_empty_base_classes = true;
   auto child_count = type.GetNumChildren(omit_empty_base_classes, &exe_ctx);
   return child_count <= max ? child_count : max;
 }

 uint64_t ValueObjectVariable::GetByteSize() {
   ExecutionContext exe_ctx(GetExecutionContextRef());

   CompilerType type(GetCompilerType());

   if (!type.IsValid())
     return 0;

   return type.GetByteSize(exe_ctx.GetBestExecutionContextScope()).getValueOr(0);
 }

 lldb::ValueType ValueObjectVariable::GetValueType() const {
   if (m_variable_sp)
     return m_variable_sp->GetScope();
   return lldb::eValueTypeInvalid;
 }

 bool ValueObjectVariable::UpdateValue() {
   SetValueIsValid(false);
   m_error.Clear();

   Variable *variable = m_variable_sp.get();
   DWARFExpression &expr = variable->LocationExpression();

   if (variable->GetLocationIsConstantValueData()) {
     // expr doesn't contain DWARF bytes, it contains the constant variable
     // value bytes themselves...
     if (expr.GetExpressionData(m_data))
       m_value.SetContext(Value::eContextTypeVariable, variable);
     else
       m_error.SetErrorString("empty constant data");
     // constant bytes can't be edited - sorry
     m_resolved_value.SetContext(Value::eContextTypeInvalid, NULL);
   } else {
     lldb::addr_t loclist_base_load_addr = LLDB_INVALID_ADDRESS;
     ExecutionContext exe_ctx(GetExecutionContextRef());

     Target *target = exe_ctx.GetTargetPtr();
     if (target) {
       m_data.SetByteOrder(target->GetArchitecture().GetByteOrder());
       m_data.SetAddressByteSize(target->GetArchitecture().GetAddressByteSize());
     }

     if (expr.IsLocationList()) {
       SymbolContext sc;
       variable->CalculateSymbolContext(&sc);
       if (sc.function)
         loclist_base_load_addr =
             sc.function->GetAddressRange().GetBaseAddress().GetLoadAddress(
                 target);
     }
     Value old_value(m_value);
     if (expr.Evaluate(&exe_ctx, nullptr, loclist_base_load_addr, nullptr,
                       nullptr, m_value, &m_error)) {
       m_resolved_value = m_value;
       m_value.SetContext(Value::eContextTypeVariable, variable);

       CompilerType compiler_type = GetCompilerType();
       if (compiler_type.IsValid())
         m_value.SetCompilerType(compiler_type);

       Value::ValueType value_type = m_value.GetValueType();

       Process *process = exe_ctx.GetProcessPtr();
       const bool process_is_alive = process && process->IsAlive();
       const uint32_t type_info = compiler_type.GetTypeInfo();
       const bool is_pointer_or_ref =
           (type_info & (lldb::eTypeIsPointer | lldb::eTypeIsReference)) != 0;

       switch (value_type) {
       case Value::eValueTypeFileAddress:
         // If this type is a pointer, then its children will be considered load
         // addresses if the pointer or reference is dereferenced, but only if
         // the process is alive.
         //
         // There could be global variables like in the following code:
         // struct LinkedListNode { Foo* foo; LinkedListNode* next; };
         // Foo g_foo1;
         // Foo g_foo2;
         // LinkedListNode g_second_node = { &g_foo2, NULL };
         // LinkedListNode g_first_node = { &g_foo1, &g_second_node };
         //
         // When we aren't running, we should be able to look at these variables
         // using the "target variable" command. Children of the "g_first_node"
         // always will be of the same address type as the parent. But children
         // of the "next" member of LinkedListNode will become load addresses if
         // we have a live process, or remain what a file address if it what a
         // file address.
         if (process_is_alive && is_pointer_or_ref)
           SetAddressTypeOfChildren(eAddressTypeLoad);
         else
           SetAddressTypeOfChildren(eAddressTypeFile);
         break;
       case Value::eValueTypeHostAddress:
         // Same as above for load addresses, except children of pointer or refs
         // are always load addresses. Host addresses are used to store freeze
         // dried variables. If this type is a struct, the entire struct
         // contents will be copied into the heap of the
         // LLDB process, but we do not currently follow any pointers.
         if (is_pointer_or_ref)
           SetAddressTypeOfChildren(eAddressTypeLoad);
         else
           SetAddressTypeOfChildren(eAddressTypeHost);
         break;
       case Value::eValueTypeLoadAddress:
       case Value::eValueTypeScalar:
       case Value::eValueTypeVector:
         SetAddressTypeOfChildren(eAddressTypeLoad);
         break;
       }

       switch (value_type) {
       case Value::eValueTypeVector:
       // fall through
       case Value::eValueTypeScalar:
         // The variable value is in the Scalar value inside the m_value. We can
         // point our m_data right to it.
         m_error =
             m_value.GetValueAsData(&exe_ctx, m_data, 0, GetModule().get());
         break;

       case Value::eValueTypeFileAddress:
       case Value::eValueTypeLoadAddress:
       case Value::eValueTypeHostAddress:
         // The DWARF expression result was an address in the inferior process.
         // If this variable is an aggregate type, we just need the address as
         // the main value as all child variable objects will rely upon this
         // location and add an offset and then read their own values as needed.
         // If this variable is a simple type, we read all data for it into
         // m_data. Make sure this type has a value before we try and read it

         // If we have a file address, convert it to a load address if we can.
         if (value_type == Value::eValueTypeFileAddress && process_is_alive)
           m_value.ConvertToLoadAddress(GetModule().get(), target);

         if (!CanProvideValue()) {
           // this value object represents an aggregate type whose children have
           // values, but this object does not. So we say we are changed if our
           // location has changed.
           SetValueDidChange(value_type != old_value.GetValueType() ||
                             m_value.GetScalar() != old_value.GetScalar());
         } else {
           // Copy the Value and set the context to use our Variable so it can
           // extract read its value into m_data appropriately
           Value value(m_value);
           value.SetContext(Value::eContextTypeVariable, variable);
           m_error =
               value.GetValueAsData(&exe_ctx, m_data, 0, GetModule().get());

           SetValueDidChange(value_type != old_value.GetValueType() ||
                             m_value.GetScalar() != old_value.GetScalar());
         }
         break;
       }

       SetValueIsValid(m_error.Success());
     } else {
       // could not find location, won't allow editing
       m_resolved_value.SetContext(Value::eContextTypeInvalid, NULL);
     }
   }
   return m_error.Success();
 }

 bool ValueObjectVariable::IsInScope() {
   const ExecutionContextRef &exe_ctx_ref = GetExecutionContextRef();
   if (exe_ctx_ref.HasFrameRef()) {
     ExecutionContext exe_ctx(exe_ctx_ref);
     StackFrame *frame = exe_ctx.GetFramePtr();
     if (frame) {
       return m_variable_sp->IsInScope(frame);
     } else {
       // This ValueObject had a frame at one time, but now we can't locate it,
       // so return false since we probably aren't in scope.
       return false;
     }
   }
   // We have a variable that wasn't tied to a frame, which means it is a global
   // and is always in scope.
   return true;
 }

 lldb::ModuleSP ValueObjectVariable::GetModule() {
   if (m_variable_sp) {
     SymbolContextScope *sc_scope = m_variable_sp->GetSymbolContextScope();
     if (sc_scope) {
       return sc_scope->CalculateSymbolContextModule();
     }
   }
   return lldb::ModuleSP();
 }

 SymbolContextScope *ValueObjectVariable::GetSymbolContextScope() {
   if (m_variable_sp)
     return m_variable_sp->GetSymbolContextScope();
   return NULL;
 }

 bool ValueObjectVariable::GetDeclaration(Declaration &decl) {
   if (m_variable_sp) {
     decl = m_variable_sp->GetDeclaration();
     return true;
   }
   return false;
 }

 const char *ValueObjectVariable::GetLocationAsCString() {
   if (m_resolved_value.GetContextType() == Value::eContextTypeRegisterInfo)
     return GetLocationAsCStringImpl(m_resolved_value, m_data);
   else
     return ValueObject::GetLocationAsCString();
 }

 bool ValueObjectVariable::SetValueFromCString(const char *value_str,
                                               Status &error) {
   if (!UpdateValueIfNeeded()) {
     error.SetErrorString("unable to update value before writing");
     return false;
   }

   if (m_resolved_value.GetContextType() == Value::eContextTypeRegisterInfo) {
     RegisterInfo *reg_info = m_resolved_value.GetRegisterInfo();
     ExecutionContext exe_ctx(GetExecutionContextRef());
     RegisterContext *reg_ctx = exe_ctx.GetRegisterContext();
     RegisterValue reg_value;
     if (!reg_info || !reg_ctx) {
       error.SetErrorString("unable to retrieve register info");
       return false;
     }
     error = reg_value.SetValueFromString(reg_info, llvm::StringRef(value_str));
     if (error.Fail())
       return false;
     if (reg_ctx->WriteRegister(reg_info, reg_value)) {
       SetNeedsUpdate();
       return true;
     } else {
       error.SetErrorString("unable to write back to register");
       return false;
     }
   } else
     return ValueObject::SetValueFromCString(value_str, error);
 }

 bool ValueObjectVariable::SetData(DataExtractor &data, Status &error) {
   if (!UpdateValueIfNeeded()) {
     error.SetErrorString("unable to update value before writing");
     return false;
   }

   if (m_resolved_value.GetContextType() == Value::eContextTypeRegisterInfo) {
     RegisterInfo *reg_info = m_resolved_value.GetRegisterInfo();
     ExecutionContext exe_ctx(GetExecutionContextRef());
     RegisterContext *reg_ctx = exe_ctx.GetRegisterContext();
     RegisterValue reg_value;
     if (!reg_info || !reg_ctx) {
       error.SetErrorString("unable to retrieve register info");
       return false;
     }
     error = reg_value.SetValueFromData(reg_info, data, 0, true);
     if (error.Fail())
       return false;
     if (reg_ctx->WriteRegister(reg_info, reg_value)) {
       SetNeedsUpdate();
       return true;
     } else {
       error.SetErrorString("unable to write back to register");
       return false;
     }
   } else
     return ValueObject::SetData(data, error);
 }
	//===-- ValueObjectVariable.cpp ---------------------------------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#include "lldb/Core/ValueObjectVariable.h"

	#include "lldb/Core/Address.h"
	#include "lldb/Core/AddressRange.h"
	#include "lldb/Core/Module.h"
	#include "lldb/Core/Value.h"
	#include "lldb/Expression/DWARFExpression.h"
	#include "lldb/Symbol/Declaration.h"
	#include "lldb/Symbol/Function.h"
	#include "lldb/Symbol/ObjectFile.h"
	#include "lldb/Symbol/SymbolContext.h"
	#include "lldb/Symbol/SymbolContextScope.h"
	#include "lldb/Symbol/Type.h"
	#include "lldb/Symbol/Variable.h"
	#include "lldb/Target/ExecutionContext.h"
	#include "lldb/Target/Process.h"
	#include "lldb/Target/RegisterContext.h"
	#include "lldb/Target/Target.h"
	#include "lldb/Utility/DataExtractor.h"
	#include "lldb/Utility/RegisterValue.h"
	#include "lldb/Utility/Scalar.h"
	#include "lldb/Utility/Status.h"
	#include "lldb/lldb-private-enumerations.h"
	#include "lldb/lldb-types.h"

	#include "llvm/ADT/StringRef.h"

	#include <assert.h>
	#include <memory>

	namespace lldb_private {
	class ExecutionContextScope;
	}
	namespace lldb_private {
	class StackFrame;
	}
	namespace lldb_private {
	struct RegisterInfo;
	}
	using namespace lldb_private;

	lldb::ValueObjectSP
	ValueObjectVariable::Create(ExecutionContextScope *exe_scope,
	const lldb::VariableSP &var_sp) {
	return (new ValueObjectVariable(exe_scope, var_sp))->GetSP();
	}

	ValueObjectVariable::ValueObjectVariable(ExecutionContextScope *exe_scope,
	const lldb::VariableSP &var_sp)
	: ValueObject(exe_scope), m_variable_sp(var_sp) {
	// Do not attempt to construct one of these objects with no variable!
	assert(m_variable_sp.get() != NULL);
	m_name = var_sp->GetName();
	}

	ValueObjectVariable::~ValueObjectVariable() {}

	CompilerType ValueObjectVariable::GetCompilerTypeImpl() {
	Type *var_type = m_variable_sp->GetType();
	if (var_type)
	return var_type->GetForwardCompilerType();
	return CompilerType();
	}

	ConstString ValueObjectVariable::GetTypeName() {
	Type *var_type = m_variable_sp->GetType();
	if (var_type)
	return var_type->GetName();
	return ConstString();
	}

	ConstString ValueObjectVariable::GetDisplayTypeName() {
	Type *var_type = m_variable_sp->GetType();
	if (var_type)
	return var_type->GetForwardCompilerType().GetDisplayTypeName();
	return ConstString();
	}

	ConstString ValueObjectVariable::GetQualifiedTypeName() {
	Type *var_type = m_variable_sp->GetType();
	if (var_type)
	return var_type->GetQualifiedName();
	return ConstString();
	}

	size_t ValueObjectVariable::CalculateNumChildren(uint32_t max) {
	CompilerType type(GetCompilerType());

	if (!type.IsValid())
	return 0;

	ExecutionContext exe_ctx(GetExecutionContextRef());
	const bool omit_empty_base_classes = true;
	auto child_count = type.GetNumChildren(omit_empty_base_classes, &exe_ctx);
	return child_count <= max ? child_count : max;
	}

	uint64_t ValueObjectVariable::GetByteSize() {
	ExecutionContext exe_ctx(GetExecutionContextRef());

	CompilerType type(GetCompilerType());

	if (!type.IsValid())
	return 0;

	return type.GetByteSize(exe_ctx.GetBestExecutionContextScope()).getValueOr(0);
	}

	lldb::ValueType ValueObjectVariable::GetValueType() const {
	if (m_variable_sp)
	return m_variable_sp->GetScope();
	return lldb::eValueTypeInvalid;
	}

	bool ValueObjectVariable::UpdateValue() {
	SetValueIsValid(false);
	m_error.Clear();

	Variable *variable = m_variable_sp.get();
	DWARFExpression &expr = variable->LocationExpression();

	if (variable->GetLocationIsConstantValueData()) {
	// expr doesn't contain DWARF bytes, it contains the constant variable
	// value bytes themselves...
	if (expr.GetExpressionData(m_data))
	m_value.SetContext(Value::eContextTypeVariable, variable);
	else
	m_error.SetErrorString("empty constant data");
	// constant bytes can't be edited - sorry
	m_resolved_value.SetContext(Value::eContextTypeInvalid, NULL);
	} else {
	lldb::addr_t loclist_base_load_addr = LLDB_INVALID_ADDRESS;
	ExecutionContext exe_ctx(GetExecutionContextRef());

	Target *target = exe_ctx.GetTargetPtr();
	if (target) {
	m_data.SetByteOrder(target->GetArchitecture().GetByteOrder());
	m_data.SetAddressByteSize(target->GetArchitecture().GetAddressByteSize());
	}

	if (expr.IsLocationList()) {
	SymbolContext sc;
	variable->CalculateSymbolContext(&sc);
	if (sc.function)
	loclist_base_load_addr =
	sc.function->GetAddressRange().GetBaseAddress().GetLoadAddress(
	target);
	}
	Value old_value(m_value);
	if (expr.Evaluate(&exe_ctx, nullptr, loclist_base_load_addr, nullptr,
	nullptr, m_value, &m_error)) {
	m_resolved_value = m_value;
	m_value.SetContext(Value::eContextTypeVariable, variable);

	CompilerType compiler_type = GetCompilerType();
	if (compiler_type.IsValid())
	m_value.SetCompilerType(compiler_type);

	Value::ValueType value_type = m_value.GetValueType();

	Process *process = exe_ctx.GetProcessPtr();
	const bool process_is_alive = process && process->IsAlive();
	const uint32_t type_info = compiler_type.GetTypeInfo();
	const bool is_pointer_or_ref =
	(type_info & (lldb::eTypeIsPointer \| lldb::eTypeIsReference)) != 0;

	switch (value_type) {
	case Value::eValueTypeFileAddress:
	// If this type is a pointer, then its children will be considered load
	// addresses if the pointer or reference is dereferenced, but only if
	// the process is alive.
	//
	// There could be global variables like in the following code:
	// struct LinkedListNode { Foo* foo; LinkedListNode* next; };
	// Foo g_foo1;
	// Foo g_foo2;
	// LinkedListNode g_second_node = { &g_foo2, NULL };
	// LinkedListNode g_first_node = { &g_foo1, &g_second_node };
	//
	// When we aren't running, we should be able to look at these variables
	// using the "target variable" command. Children of the "g_first_node"
	// always will be of the same address type as the parent. But children
	// of the "next" member of LinkedListNode will become load addresses if
	// we have a live process, or remain what a file address if it what a
	// file address.
	if (process_is_alive && is_pointer_or_ref)
	SetAddressTypeOfChildren(eAddressTypeLoad);
	else
	SetAddressTypeOfChildren(eAddressTypeFile);
	break;
	case Value::eValueTypeHostAddress:
	// Same as above for load addresses, except children of pointer or refs
	// are always load addresses. Host addresses are used to store freeze
	// dried variables. If this type is a struct, the entire struct
	// contents will be copied into the heap of the
	// LLDB process, but we do not currently follow any pointers.
	if (is_pointer_or_ref)
	SetAddressTypeOfChildren(eAddressTypeLoad);
	else
	SetAddressTypeOfChildren(eAddressTypeHost);
	break;
	case Value::eValueTypeLoadAddress:
	case Value::eValueTypeScalar:
	case Value::eValueTypeVector:
	SetAddressTypeOfChildren(eAddressTypeLoad);
	break;
	}

	switch (value_type) {
	case Value::eValueTypeVector:
	// fall through
	case Value::eValueTypeScalar:
	// The variable value is in the Scalar value inside the m_value. We can
	// point our m_data right to it.
	m_error =
	m_value.GetValueAsData(&exe_ctx, m_data, 0, GetModule().get());
	break;

	case Value::eValueTypeFileAddress:
	case Value::eValueTypeLoadAddress:
	case Value::eValueTypeHostAddress:
	// The DWARF expression result was an address in the inferior process.
	// If this variable is an aggregate type, we just need the address as
	// the main value as all child variable objects will rely upon this
	// location and add an offset and then read their own values as needed.
	// If this variable is a simple type, we read all data for it into
	// m_data. Make sure this type has a value before we try and read it

	// If we have a file address, convert it to a load address if we can.
	if (value_type == Value::eValueTypeFileAddress && process_is_alive)
	m_value.ConvertToLoadAddress(GetModule().get(), target);

	if (!CanProvideValue()) {
	// this value object represents an aggregate type whose children have
	// values, but this object does not. So we say we are changed if our
	// location has changed.
	SetValueDidChange(value_type != old_value.GetValueType() \|\|
	m_value.GetScalar() != old_value.GetScalar());
	} else {
	// Copy the Value and set the context to use our Variable so it can
	// extract read its value into m_data appropriately
	Value value(m_value);
	value.SetContext(Value::eContextTypeVariable, variable);
	m_error =
	value.GetValueAsData(&exe_ctx, m_data, 0, GetModule().get());

	SetValueDidChange(value_type != old_value.GetValueType() \|\|
	m_value.GetScalar() != old_value.GetScalar());
	}
	break;
	}

	SetValueIsValid(m_error.Success());
	} else {
	// could not find location, won't allow editing
	m_resolved_value.SetContext(Value::eContextTypeInvalid, NULL);
	}
	}
	return m_error.Success();
	}

	bool ValueObjectVariable::IsInScope() {
	const ExecutionContextRef &exe_ctx_ref = GetExecutionContextRef();
	if (exe_ctx_ref.HasFrameRef()) {
	ExecutionContext exe_ctx(exe_ctx_ref);
	StackFrame *frame = exe_ctx.GetFramePtr();
	if (frame) {
	return m_variable_sp->IsInScope(frame);
	} else {
	// This ValueObject had a frame at one time, but now we can't locate it,
	// so return false since we probably aren't in scope.
	return false;
	}
	}
	// We have a variable that wasn't tied to a frame, which means it is a global
	// and is always in scope.
	return true;
	}

	lldb::ModuleSP ValueObjectVariable::GetModule() {
	if (m_variable_sp) {
	SymbolContextScope *sc_scope = m_variable_sp->GetSymbolContextScope();
	if (sc_scope) {
	return sc_scope->CalculateSymbolContextModule();
	}
	}
	return lldb::ModuleSP();
	}

	SymbolContextScope *ValueObjectVariable::GetSymbolContextScope() {
	if (m_variable_sp)
	return m_variable_sp->GetSymbolContextScope();
	return NULL;
	}

	bool ValueObjectVariable::GetDeclaration(Declaration &decl) {
	if (m_variable_sp) {
	decl = m_variable_sp->GetDeclaration();
	return true;
	}
	return false;
	}

	const char *ValueObjectVariable::GetLocationAsCString() {
	if (m_resolved_value.GetContextType() == Value::eContextTypeRegisterInfo)
	return GetLocationAsCStringImpl(m_resolved_value, m_data);
	else
	return ValueObject::GetLocationAsCString();
	}

	bool ValueObjectVariable::SetValueFromCString(const char *value_str,
	Status &error) {
	if (!UpdateValueIfNeeded()) {
	error.SetErrorString("unable to update value before writing");
	return false;
	}

	if (m_resolved_value.GetContextType() == Value::eContextTypeRegisterInfo) {
	RegisterInfo *reg_info = m_resolved_value.GetRegisterInfo();
	ExecutionContext exe_ctx(GetExecutionContextRef());
	RegisterContext *reg_ctx = exe_ctx.GetRegisterContext();
	RegisterValue reg_value;
	if (!reg_info \|\| !reg_ctx) {
	error.SetErrorString("unable to retrieve register info");
	return false;
	}
	error = reg_value.SetValueFromString(reg_info, llvm::StringRef(value_str));
	if (error.Fail())
	return false;
	if (reg_ctx->WriteRegister(reg_info, reg_value)) {
	SetNeedsUpdate();
	return true;
	} else {
	error.SetErrorString("unable to write back to register");
	return false;
	}
	} else
	return ValueObject::SetValueFromCString(value_str, error);
	}

	bool ValueObjectVariable::SetData(DataExtractor &data, Status &error) {
	if (!UpdateValueIfNeeded()) {
	error.SetErrorString("unable to update value before writing");
	return false;
	}

	if (m_resolved_value.GetContextType() == Value::eContextTypeRegisterInfo) {
	RegisterInfo *reg_info = m_resolved_value.GetRegisterInfo();
	ExecutionContext exe_ctx(GetExecutionContextRef());
	RegisterContext *reg_ctx = exe_ctx.GetRegisterContext();
	RegisterValue reg_value;
	if (!reg_info \|\| !reg_ctx) {
	error.SetErrorString("unable to retrieve register info");
	return false;
	}
	error = reg_value.SetValueFromData(reg_info, data, 0, true);
	if (error.Fail())
	return false;
	if (reg_ctx->WriteRegister(reg_info, reg_value)) {
	SetNeedsUpdate();
	return true;
	} else {
	error.SetErrorString("unable to write back to register");
	return false;
	}
	} else
	return ValueObject::SetData(data, error);
	}